Semiconductor die with improved thermal insulation between a power portion and a peripheral portion, method of manufacturing, and package housing the die

ABSTRACT

A semiconductor die includes a structural body that has a power region and a peripheral region surrounding the power region. At least one power device is positioned in the power region. Trench-insulation means extend in the structural body starting from the front side towards the back side along a first direction, adapted to hinder conduction of heat from the power region towards the peripheral region along a second direction orthogonal to the first direction. The trench-insulation means have an extension, in the second direction, greater than the thickness of the structural body along the first direction.

BACKGROUND Technical Field

The present disclosure relates to a semiconductor die, a method of manufacturing the semiconductor die, and a package housing the semiconductor die.

Description of the Related Art

GaN-based semiconductor devices are attracting considerable attention for power-electronics applications on account of their properties, such as the high breakdown electrical field, the high carrier density, the high electron mobility, and the high saturation rate. There are, on the other hand, known technologies for implementation of smart power integrated circuits (smart power ICs), based upon GaN-on-Silicon (GaN-on-Si) platforms having large dimensions, low cost, and high scalability.

Currently, high-voltage power components (e.g., power transistors, GaN-based HEMT (high electron mobility transistor) devices, etc.) are manufactured on, or bonded to, chips that house low-voltage peripheral devices and that form mixed digital/analog circuits. In particular, analog functional blocks, such as reference-voltage generators, voltage comparators, and voltage converters, have been obtained exploiting GaN-based technology in association with a peripheral circuitry obtained with CMOS silicon technology.

In the aforementioned technical solutions, the peripheral circuitry has, for example, the function of protection and/or control of the power components, and is necessary for guaranteeing a robust control, a greater functionality, and greater reliability of the high-voltage power components, for example, against harmful operating conditions, as in the case of over-currents and over-voltages.

It is highly desirable to integrate power devices in the same chip that houses the peripheral functional blocks, thus increasing the density of integration as far as possible.

However, the performance of the peripheral circuits, as likewise those of power devices, is dependent upon temperature. An excessively high temperature, generated by the power devices, may cause malfunctioning of the peripheral circuitry or, in extreme conditions, burning-out of the chip or of parts thereof.

Solutions for managing the temperature at a circuit level have been proposed, e.g., over temperature protection circuits; likewise, cooling solutions are known that envisage the use of heat dissipaters at the package level.

The above solutions, however, are not satisfactory when the density of integration increases and the distances between the electronic power devices and the peripheral circuitry are smaller.

BRIEF SUMMARY

The present disclosure provides a semiconductor die, a method of manufacturing the semiconductor die, and a package housing the semiconductor die that overcome the limitations of the prior art.

According to the present disclosure, a semiconductor die, a method of manufacturing the semiconductor die, and a package housing the semiconductor die are provided, as defined in the annexed claims.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

For a better understanding of the present disclosure, some embodiments thereof is now described, purely by way of non-limiting example, with reference to the attached drawings, wherein:

FIG. 1 is a cross-section view of a portion of a die provided with an electrical-insulation region between a power region and a peripheral region, taken along the line of section I-I of FIG. 2 , according to some embodiments of the present invention;

FIG. 2 is a top plan view of the die of FIG. 1 ;

FIG. 3 is a cross-section view of a portion of a die provided with an electrical-insulation region between a power region and a peripheral region, according to some embodiments of the present disclosure;

FIG. 4 illustrates a portion of a package housing the die of FIG. 1 or FIG. 3 ; and

FIGS. 5 to 7 illustrate variations of manufacturing of the power region of the die of FIG. 1 or FIG. 3 , in accordance with some embodiments.

DETAILED DESCRIPTION

FIG. 1 illustrates, in a side section view in a triaxial cartesian reference system X, Y, Z, a portion of a die 1 according to an aspect of the present disclosure. The elements illustrated in FIG. 1 are not represented in the same scale, but are represented schematically and by way of example, in order to facilitate understanding of the present disclosure.

The die 1 comprises: a substrate 2, made of a semiconductor material, for example, silicon, and for example, silicon with a P-type doping, having a front side 2 a and a back side 2 b, opposite to each other along the direction of the axis Z; an epitaxial layer 4, made of epitaxially grown silicon, for example, with a N-type doping, which extends over the front side 2 a of the substrate 2; and a dielectric layer 6, made, for example, of silicon oxide (SiO₂), which extends over a top face 4 a of the epitaxial layer 4.

It is appreciated that between the substrate 2 and the epitaxial layer 4, further epitaxial layers, or layers of some other type (not illustrated) may be present. In what follows, the ensemble of the substrate 2 and the epitaxial layer 4, including said possible further layers if present, will be referred to as “structural body 3”, which has a thickness, considered along the axis X between the top face 4 a of the epitaxial layer 4 and the back side 2 b of the substrate 2, denoted by h. As will be more appreciated in the following description, the possible further layers present are of a thermally conductive material, indicatively, with a thermal conductivity comparable to, or higher than, that of the materials of the substrate 2 and/or of the epitaxial layer 4.

According to an aspect of the present disclosure, to enable a high density of integration, a planar process is used for the manufacturing of high-voltage power devices 10 and of low-voltage peripheral devices 8, e.g., obtained with CMOS technology, which implement functional blocks adapted to control/support operation of the power devices.

The layout of the die 1 may be organized so as to group together, in one and the same region of the die 1, the high-voltage power devices 10, and group together in one and the same respective region of the die 1 the low-voltage peripheral devices 8. In particular, the low-voltage peripheral devices 8 are formed in a region that surrounds, in top plan view (in the plane XY), the region that houses the high-voltage power devices 10.

For this purpose, with reference to FIGS. 1 and 2 , the die 1, or specifically, the structural body 3, comprises a first region 1 a that houses the low-voltage peripheral devices 8. In some embodiments, the low-voltage peripheral devices 8 are integrated in the structural body 3, and at least partly in the epitaxial layer 4. In what follows, the first region 1 a will also be referred to as “peripheral region 1 a”, and the components housed therein will also be referred to as “peripheral components 8”. Extending on the dielectric layer 6 are one or more electrical-contact pads 7, electrically coupled to the peripheral components 8 by means of conductive through vias and metal layers, generically designated by the reference number 9.

The die 1, or specifically, the structural body 3, further comprises a second region 1 b that houses one or more high-voltage power devices 10, which include, for example, one or more GaN-based HEMTs. In general, the high-voltage power devices 10 dissipate, when the device is in operation, thermal energy of the order of hundreds of microjoules. In what follows, this second region 1 b will also be referred to as “power region 1 b”, and the high-voltage power devices 10 will also be referred to as “power devices 10”.

By way of example, the components/circuits of the peripheral region 1 a and of the power region 1 b form, together, a DC/DC converter, where the components/circuits of the peripheral region 1 a form the control part, e.g., pre-amplification circuits, driving circuit for biasing the gate terminal or terminals, etc., of the DC/DC converter, whereas the power devices housed in the power region 1 b form the switch elements of the DC/DC converter.

The die 1, or specifically, the structural body 3, further comprises a third region 1 c, which extends, in top plan view (e.g., in the plane XY), between the first region 1 a and the second region 1 b, and houses one or more trenches 12 adapted to form an obstacle for lateral thermal propagation of the heat generated, when the device is in operation, by the power devices 10 in the power region 1 b. As illustrated in the figure, the arrows T2, which represent the propagation of heat in the direction X, are intercepted and hindered by the trenches 12. In what follows, the third region 1 c will also be referred to as “thermal-insulation region 1 c”.

FIG. 2 illustrates the die of FIG. 1 in top plan view, in the plane XY. In some embodiments, the section view of FIG. 1 is, in particular, taken along the line of section I-I of FIG. 2 . As may be noted from FIG. 2 , the thermal-insulation region 1 c extends so as to completely surround the power region 1 b. In turn, the peripheral region 1 a extends so that it completely surrounds the thermal-insulation region 1 c.

The function of the thermal-insulation region 1 c is, as has been said, that of providing an obstacle for the propagation or transfer of the heat generated, when the device is in operation, in the power region 1 b, towards the peripheral region 1 a. It is appreciated that, in the case where the peripheral region 1 a extends facing or adjacent to part of the power region 1 b, e.g., the peripheral region 1 does not surround the power region 1 b completely, the thermal-insulation region 1 c can extend between the peripheral region 1 a and the power region 1 b, without surrounding the latter completely.

In any direction of thermal propagation considered (i.e., along X, along Y, or in directions that have a component both along X and along Y), the heat generated at the power region 1 b is intercepted by the trenches 12 of the thermal-insulation region 1 c.

Returning to FIG. 1 , the one or more trenches 12 (here a plurality of trenches 12 are illustrated by way of example) include a first filling layer 12 a of dielectric material (e.g., SiO₂) and a second filling layer 12 b, completely contained within the first filling layer 12 a. In some embodiments, the second filling layer 12 b is made of a material adapted to compensate for the thermal stress that, when the device is in operation, is generated at the trenches 12. The present applicant has in fact noted that, on account of the different thermal expansions of the silicon oxide of the filling layer 12 a with respect to the silicon of the structural body 3, the filling layer 12 a may be subject to physical damage. Use of the second filling layer 12 b, here for example polysilicon, enables this undesired phenomenon to be overcome.

It is, however, appreciated that, in the case where the structural body 3 and the first filling layer 12 a are made of materials such that the undesired phenomenon mentioned above is not present, the second filling layer 12 b may be omitted. Moreover, irrespectively of the materials used, the second filling layer 12 b may be omitted also in the case where the specific operating application of the die 1 is such that no thermal stress is generated such as to cause damage to the trenches 12.

In general, the first filling layer 12 a is made of a thermally insulating material, i.e., a material having a thermal conductivity approximately equal to 1 W/mK.

The trenches 12 extend in depth in the structural body 3, starting from the top face 4 a of the epitaxial layer 4, completely through the epitaxial layer 4 and through part of the substrate 2, terminating within the substrate 2. These embodiments present the advantage of forming the trenches 12 simultaneously with trench regions for electrical insulation between devices/components in the peripheral region 1 a. In fact, it is known to electrically insulate electronic components from one another, for example transistors, by means of trenches filled with dielectric material. During processing of the die 1, the step of forming such electrical-insulation trenches further comprises the simultaneous step of forming the thermal-insulation trenches 12. The manufacturing costs are thus reduced, and the production process is speeded up.

Alternatively or additionally, it is, however, possible to form the trenches 12 in a separate step. In this case, the depth of the trenches 12 is not constrained to the depth of the trenches present in the peripheral region 1 a. In particular, the trenches 12 may extend through just the thickness of the epitaxial layer 4 or, in general, terminate at the front side 2 a of the substrate 2.

According to some further embodiments, illustrated in FIG. 3 , one or more of the trenches 12 (in FIG. 3 , all of the trenches 12) may extend throughout the entire thickness of the structural body 3, i.e., completely through the epitaxial layer 4 and through the substrate 2 until reaching the back side 2 b of the substrate 2.

The heat generated, in use, in the power region 1 b propagates through the structural body 3. Among the various possible directions of propagation, the arrow T1 in FIG. 1 identifies a direction of vertical propagation, along the direction of the axis Z, towards the back side 2 b of the substrate 2. Likewise identified in FIG. 1 is a first direction of lateral propagation, along the axis X, indicated by the arrow T2. This heat propagation in the direction T2 is hindered by the presence of the trenches 12. Furthermore, a second lateral direction of propagation, along the axis X, is indicated by the arrow T3, through the substrate 2 in the region of the latter without the trenches 12.

The thermal-insulation region 1 c has a lateral extension d, along the direction of the axis X, such that the thermal path T3 will have a greater distance than the thermal path T1. To meet this requirement, in the design step, there is conservatively chosen a value of d greater than the value of h, where h is, as has been said, the thickness of the structural body 3. The lateral extension d is given, more in particular, by the sum of the extensions, along X, of each trench 12 plus the extension, once again along X, of the portion of the structural body 3 ranging between one trench 12 and the adjacent trench 12.

The number, the material and lateral extension of the trenches 12 are also chosen so that the trenches 12 will offer an adequate thermal insulation in regard to the thermal wave T2, e.g., such that the heat propagating through them along the direction of the axis X (arrows T2′) as far as the peripheral region 1 a, will be lower than a threshold pre-set in the design step.

The design of the trenches 12 (for example, in terms of number of trenches, materials, and thicknesses of the filling layers, lateral extension of the trenches, etc.) may be performed by means of simulation programs, in a way appreciated to the person skilled in the art.

It is clear that what has been described above with particular reference to the direction of thermal propagation along X (in particular, with reference to the lateral extension d of the thermal-insulation region 1 c) applies to any direction of thermal propagation considered, i.e., along X, along Y, and in directions that have a component both along X and along Y.

The trenches 12 hence delimit a path, or channel, of preferential propagation of the heat that is generated in the power region 1 b, which hence propagates preferentially towards the back side 2 b of the substrate 2.

As illustrated schematically in FIG. 4 , the die 1 is coupled, during packaging, to a base plate 20 made of thermally conductive material, in particular metal material such as copper, of a package 25 (only a portion of the package 25 is illustrated in FIG. 4 ). The base plate 20 of the package 25 is adapted to support the die 1 and is made of thermally conductive material to favor dissipation of the heat generated, in use, by the power devices 10. Typically, the base plate 20 is thermally coupled to a heat dissipater 22.

Hence, in use, the heat that propagates along T1, or that in general reaches the back side of the substrate 2, is transferred to the base plate 20 of the package 25 and then dissipated by means of the heat dissipater 22.

FIG. 5 illustrates an enlarged detail of the power region 1 b of the die 1. In some embodiments, the power devices (here in particular only a GaN-based HEMT device 10 is illustrated) are formed on the structural body 3 in manufacturing steps that are simultaneous or subsequent to the manufacturing steps of the peripheral components 8. Manufacture of a GaN-based HEMT device is in itself known and not described herein in so far as it does not form the subject of the present disclosure. The device 10 includes a heterostructure 10 a formed by a channel layer 10 b, extending on which is a barrier layer 10 c, made of aluminum and gallium nitride (AlGaN). An insulation layer 10 d, made of dielectric material, extends on the barrier layer 10 c. A gate terminal 10 e extends on the barrier layer 10 c between a source terminal 10 f and a drain terminal 10 g.

To favor adhesion of the channel layer 10 b of the device 10 to the structural body 3 of the die 1 an interface layer 26 made of aluminum nitride is present. The interface layer 26 has the function of forming an interface for lattice adaptation between the crystal lattice of the epitaxial layer 4 (which is here made of silicon) and the crystal lattice of the channel layer 10 b (which is here made of GaN), and likewise has the function of favoring thermal coupling between the HEMT device 10 and the underlying structural body 3.

The HEMT device 10 is of a lateral-conduction type, and has the source terminal 10 f, the drain terminal 10 g, and the gate terminal 10 e on its top side, to favor their electrical contact (e.g., via wire bonding), for biasing of the device.

In some different embodiments, illustrated in FIG. 6 in the same enlarged view as that of FIG. 5 , the one or more power devices 10 are coupled to the structural body 3 of the die 1 following upon manufacturing of the peripheral components 8 (in FIG. 6 just one single GaN-based HEMT device 10 is once again illustrated).

In this case, the HEMT device 10 has a substrate 10 h, made, for example, of Si or SiC, on which the heterostructure 10 a extends. A thermally conductive coupling region 30, for example made of thermally conductive glue or solder paste, which extends between the substrate 10 h of the HEMT device 10 and the structural body 3, coupling them together.

According to some further embodiments, illustrated in FIG. 7 , the dielectric layer 6 houses a plurality of metal layers 32 a-32 c, which form as a whole a metal stack. FIG. 7 illustrates, by way of example, a bottom layer 32 c, a top layer 32 a, and an intermediate layer 32 b, arranged between the bottom layer 32 c and the top layer 32 a. The metal layers 32 a-32 c are coupled together by means of thermally conductive through vias 34. The bottom metal layer 32 c is in thermal contact with the structural body 3 (possibly via an interface layer), whereas the top metal layer 32 a is in thermal contact with the substrate 10 h of the device 10, via the coupling region 30 (here for instance, made of solder paste, for example lead or tin). The metal layers 32 a-32 c further improve thermal coupling between the HEMT device 10 and the structural body 3. Other coupling or bonding techniques between the HEMT device 10 and the structural body 3 may be used, as is appreciated to the person skilled in the art.

From an examination of the characteristics of the present disclosure provided according to the present disclosure, the advantages that it affords are appreciated.

In particular, the present disclosure enables thermal decoupling of the low-power (CMOS) circuitry from the high-power circuitry. It is thus possible to increase the density of integration of the components on a single die without incurring malfunctioning due to the high level of heat generated, in use, by the power devices.

Finally, it is clear that modifications and variations may be made to the disclosure described and illustrated herein, without thereby departing from the scope thereof, as defined in the annexed claims.

For instance, the power devices housed in the power region 1 b include one or more of the following: lateral (LDMOSs), BJTs, power MOSs (for example, bases on SiC), IGBTs, etc.

Moreover, the components/circuits of the peripheral region 1 a and of the power region 1 b may form, together, an AC/AC cycloconverter, a DC/AC inverter, and an AC/DC rectifier.

The various embodiments described above can be combined to provide further embodiments.

These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure. 

1. (canceled)
 2. A device, comprising: a first substrate having a first conductivity type; a first layer of a second conductivity type; a first dielectric layer on the first layer; a gallium nitride high electron mobility transistor on the first dielectric layer; a first conductive layer on the first dielectric layer, the transistor being on the first conductive layer; a second conductive layer in the first dielectric layer; a plurality of first vias coupled between the first conductive layer and the second conductive layer.
 3. The device of claim 2, comprising a thermally conductive region on the first conductive layer.
 4. The device of claim 3 wherein the transistor includes a second substrate on the thermally conductive region, a first gallium nitride layer on the second substrate, and a second gallium nitride layer on the first gallium nitride layer.
 5. The device of claim 4 wherein the transistor includes a gate on the second gallium nitride layer, a dielectric is around the gate, and source and drain region are spaced from each other by the dielectric and the gate.
 6. The device of claim 5, comprising a third conductive layer in the first dielectric layer and a plurality of second vias coupled between the third conductive layer and the second conductive layer.
 7. The device of claim 6, comprising a plurality of trenches that each extend through the first layer and into the first substrate;.
 8. The device of claim 7 wherein the transistor is centrally positioned with respect to the plurality of trenches.
 9. A device, comprising: a heat dissipater; a first substrate on the first dissipater; a first semiconductor layer on the substrate; a first dielectric layer on the first semiconductor layer; a plurality of thermally insulating trenches that extend in the first semiconductor layer and in the first substrate, the plurality of thermally insulating trenches being around a central region; a gallium nitride device in the first dielectric layer, the gallium nitride device including: a second substrate on the first dielectric layer; a first gallium nitride layer on the second substrate; and a second gallium nitride layer on the first gallium nitride layer.
 10. The device of claim 9 wherein the second gallium nitride layer is an aluminum gallium nitride layer.
 11. The device of claim 10 wherein the transistor includes a gate on the second gallium nitride layer and a source and drain region beside the gate on the second gallium nitride layer.
 12. A device, comprising: a structural body of semiconductor material having a first side and a second side, the first side including a first region and a second region at least partially surrounding the first region; a base plate of a package coupled to the second side of the structural body; at least one semiconductor power device coupled to the first side of the structural body in the first region with a thermally conductive coupling interface; a trench-insulation structure between the first region and the second region, which extends along a first direction starting from the first side towards the second side, the trench-insulation structure being around a central region where the at least one semiconductor power device is coupled.
 13. The device of claim 12 wherein the trench-insulation structure has an extension, along a second direction that is transverse to the first direction, greater than a thickness of the structural body measured along the first direction from the first side to the second side.
 14. The device of claim 13 wherein the trench-insulation structure includes a plurality of mutually successive trenches along the second direction spaced apart from one another by respective separation regions.
 15. The device of claim 14 wherein the at least one semiconductor power device includes a gallium nitride high electron mobility transistor.
 16. The device of claim 15 wherein the gallium nitride transistor includes a gallium nitride layer and an aluminum gallium nitride layer on the gallium nitride layer.
 17. The device of claim 16 wherein the gallium nitride transistor including a gate and a source and drain region on the aluminum gallium nitride layer. 